Inhomogeneous minimization problems for the p(x)-Laplacian

Abstract

We study an inhomogeneous minimization problems associated to the p(x)-Laplacian. We make a thorough analysis of the essential properties of their minimizers and we establish a relationship with a suitable free boundary problem. On the one hand, we study the problem of minimizing the functional J(v)=∫(|∇ v|p(x)p(x)+λ(x)\v>0\+fv)\,dx. We show that nonnegative local minimizers u are solutions to the free boundary problem: u 0 and equation fbp-pxP(f,p,λ*) cases p(x)u:=div(|∇ u(x)|p(x)-2∇ u)= f & in \u>0\\\ u=0,\ |∇ u| = λ*(x) & on ∂\u>0\ cases equation with λ*(x)=(p(x)p(x)-1\,λ(x))1/p(x) and that the free boundary is a C1,α surface. On the other hand, we study the problem of minimizing the functional J(v)= ∫ (|∇ v|p(x)p(x)+B(v)+f v)\, dx, where B(s)=∫ 0sβ(τ) \, dτ, >0, β(s)=1 β(s ), with β a Lipschitz function satisfying β>0 in (0,1), β 0 outside (0,1). We prove that if u are nonnegative local minimizers, then any limit function u ( 0) is a solution to the free boundary problem P(f,p,λ*) with λ*(x)=(p(x)p(x)-1\,M)1/p(x), M=∫ β(s)\, ds, p= p, f= f, and that the free boundary is a C1,α surface. In order to obtain our results we need to overcome deep technical difficulties and develop new strategies, not present in the previous literature for this type of problems.